CN212841868U - Heat exchange station automatic control system based on S2100 Internet of things controller - Google Patents

Abstract

The utility model provides a heat transfer station autonomous system based on S2100 thing networking controller, it includes the heat transfer station, a pipe network, the secondary pipe network, be equipped with the heat transfer station switch board in the heat transfer station, the heat transfer station switch board includes cabinet body, this internal distribution board that can install S2100 thing networking controller that has set firmly in the cabinet, be formed with ventilation channel between distribution board and the cabinet body, and be equipped with air intake and air outlet on cabinet body, locate this internal passing device that is equipped with of cabinet, ventilation unit includes the filter equipment with the air intake intercommunication, and the drainage fan of being connected with filter equipment, drainage fan' S gas outlet is connected with the exhaust pipe that can place in ventilation channel, in order to constitute the ventilation and heat dissipation to S2100 thing networking controller. The utility model discloses a heat transfer station autonomous system based on S2100 thing networking controller not only can effectively ventilate the heat dissipation to the S2100 thing networking controller in the heat transfer station switch board through the ventilation unit who sets up, still can play better dustproof effect in the heat transfer station switch board.

Description

Heat exchange station automatic control system based on S2100 Internet of things controller

Technical Field

The utility model relates to a heating equipment technical field, in particular to heat transfer station autonomous system based on S2100 thing networking controller.

Background

With the increase of urban industrialization speed in China, the urban central heating industry is rapidly developed. The hydraulic imbalance of the heat supply network pipe network causes uneven cold and heat, which is an important problem to be solved urgently at present, on one hand, the heat demand of a heat user cannot be guaranteed, on the other hand, the heat energy of a heat supply enterprise is wasted greatly, and the current situation not only brings great inconvenience to life, work and study of people, but also causes economic loss for the heat supply enterprise. In addition, the controller is the core component of heating system, and the normal operating of equipment is extremely influenced to the good or bad of its operational environment, and current switch board is simple in construction, and has the internal dust of cabinet too much, or the internal humiture of cabinet scheduling problem such as too big and lead to the life of controller to can't guarantee the normal operating of system.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model aims at providing a heat exchange station autonomous system based on S2100 thing networking controller to can improve the operational environment of controller.

In order to achieve the above purpose, the technical scheme of the utility model is realized like this:

a heat exchange station automatic control system based on S2100 Internet of things controller includes: the heat exchange station comprises a heat exchange station, a primary pipe network and a secondary pipe network, wherein a heat exchange station control cabinet is arranged in the heat exchange station, the heat exchange station control cabinet comprises a cabinet body, a distribution board which can be provided with an S2100 Internet of things controller is fixedly arranged in the cabinet body, a ventilation channel is formed between the distribution board and the cabinet body, and an air inlet and an air outlet are formed in the cabinet body;

the ventilation device is arranged in the cabinet body and comprises a filtering device communicated with the air inlet and a drainage fan connected with the filtering device and positioned in the cabinet body, and an air outlet of the drainage fan is connected with an exhaust pipe which can be placed in the ventilation channel so as to form ventilation and heat dissipation of the S2100 Internet of things controller.

Furthermore, the longitudinal section of the distribution board is of a structure in a shape like a Chinese character 'ji', a plurality of first mounting holes in a long strip shape are formed on an edge wing plate of the distribution board, and a plurality of second mounting holes in a long strip shape are formed in the middle of the distribution board.

Furthermore, a plurality of mounting holes are formed in the S2100 internet-of-things controller, and a cylindrical rubber pad is disposed between each mounting hole and the corresponding second mounting hole.

Further, filter equipment is including nestification in an organic whole, and the diameter variation in size and be cylindric first filter core and second filter core, warp the air intake flows through extremely this internal air current of cabinet passes through in proper order the filtration of first filter core and second filter core, and by the inner chamber of second filter core is discharged.

Furthermore, the filtering device further comprises a shell with an end cover, wherein a conical air inlet hole is formed in the bottom of the shell, the first filter element and the second filter element are screwed on the end cover, and an air blowing hole is formed in the end cover at a position between the first filter element and the second filter element.

Further, a door body provided with a display unit is pivotally arranged on the cabinet body, and a sealing strip is arranged between the door body and the cabinet body.

Furthermore, a signal monitoring device is arranged on a water supply pipeline of the primary pipe network so as to monitor the temperature, pressure and flow of the water supply.

Furthermore, a temperature sensor and a pressure sensor are arranged on the water return pipeline of the primary pipe network, the water supply pipeline of the secondary pipe network and the water return pipeline of the secondary pipe network.

Compared with the prior art, the utility model discloses following advantage has:

(1) heat transfer station autonomous system based on S2100 thing networking controller, through the ventilation unit who sets up, and form the ventilation passageway between distribution board and cabinet body, not only can effectively carry out ventilation and heat dissipation to the S2100 thing networking controller in the heat transfer station switch board, still can play better dustproof effect in the switch board of heat transfer station simultaneously, still reduce the humidity of the cabinet body originally internal in addition to a certain degree, thereby can effectively guarantee S2100 thing networking controller' S operational environment, with the life who improves S2100 thing networking controller, thereby can guarantee the normal operating of system, and there is better result of use.

(2) The distribution board is of a structure in a shape like a Chinese character 'ji', the structure is simple, the distribution board is convenient to process and manufacture, and meanwhile, the first mounting hole in the shape of a long strip is convenient for being fixedly connected with the cabinet body, and the second mounting hole in the shape of a long strip is beneficial to connection and installation of the S2100 Internet of things controller and the distribution board.

(3) The cylindrical rubber pad that sets up can play the shock attenuation effect to S2100 thing networking controller on the one hand, and on the other hand makes and forms certain clearance between S2100 thing networking controller and the distribution board to under the effect of second mounting hole, can play better ventilation radiating effect.

(4) The first filter core and the second filter core that set up can carry out effective filtration to the gas that enters into the cabinet body internally.

(5) The hole of blowing that sets up to ventilate to filter equipment through the hole of blowing, thereby make the air current can flow along the reversal of filtering direction, so that be stained with the dust that attaches to on first filter core and the second filter core along with the flow of gas and discharge to the cabinet body outside this, and then can clear up filter equipment under the prerequisite of needn't dismantle filter equipment, and then extensible filter equipment's life.

(6) The sealing strip is arranged to facilitate the cabinet body to be in a relatively sealed state.

(7) The signal monitoring device is arranged so as to monitor the temperature, the pressure and the flow of the water supply of the primary pipe network.

Drawings

The accompanying drawings, which form a part hereof, are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the invention without undue limitation. In the drawings:

fig. 1 is a schematic structural diagram of a heat exchange station autonomous system based on an S2100 internet-of-things controller according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a control cabinet of a heat exchange station according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a filtering apparatus according to an embodiment of the present invention;

fig. 4 is a cross-sectional view of a filter assembly according to an embodiment of the present invention;

fig. 5 is a schematic structural diagram of a distribution board according to an embodiment of the present invention;

fig. 6 is a schematic view of an installation structure of the controller according to the embodiment of the present invention;

fig. 7 is a schematic view of an installation structure of a filtering apparatus according to an embodiment of the present invention;

description of reference numerals:

1-cabinet body, 11-air blowing port, 12-air inlet, 13-air outlet, 14-threading pipe port;

2-a door body, 21-a sealing strip, 22-a display unit;

3-filtering device, 31-air inlet hole, 32-air outlet hole, 33-air outlet hole, 34-threaded hole, 35-first filter element, 36-second filter element;

4-a drainage fan;

5-distribution board, 51-first mounting hole, 52-second mounting hole, 53-groove;

10-S2100 Internet of things controller, 20-exhaust pipe.

Detailed Description

It should be noted that, in the present invention, the embodiments and features of the embodiments may be combined with each other without conflict.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", etc. indicate the orientation or positional relationship based on the orientation or positional relationship shown in the drawings, which are only for convenience of description and simplification of description, and do not indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

The present invention will be described in detail below with reference to the accompanying drawings in conjunction with embodiments.

The embodiment relates to a heat exchange station automatic control system based on an S2100 Internet of things controller, an exemplary structure of which can be seen in a figure 1 and a figure 2, the heat exchange station automatic control system mainly comprises a heat exchange station, a primary pipe network, a secondary pipe network, a water replenishing tank, a drain tank, a pressure sensor, a temperature sensor, a flow sensor and other signal monitoring devices, wherein a heat exchange station control cabinet is arranged in the heat exchange station, the heat exchange station control cabinet comprises a cabinet body 1, a distribution board 5 which can be provided with the S2100 Internet of things controller 10 is fixedly arranged in the cabinet body 1, a ventilation channel is formed between the distribution board 5 and the cabinet body 1, and an air inlet 12 and an air outlet are arranged on the cabinet body 1. The ventilation device is arranged in the cabinet body 1 and comprises a filtering device 3 communicated with the air inlet 12 and a drainage fan 4 connected with the filtering device 3 and positioned in the cabinet body 1, and an air outlet of the drainage fan 4 is connected with an exhaust pipe 20 which can be placed in a ventilation channel so as to well ventilate and dissipate heat of the S2100 Internet of things controller 10.

Wherein, be equipped with signal monitoring devices on the water supply pipeline of a pipe network to can be to the monitoring of water supply temperature, pressure and flow. The signal monitoring device can be a temperature sensor, a pressure sensor, a flow sensor and the like in the prior art. In addition, a temperature sensor and a pressure sensor are arranged on the return pipeline of the primary pipe network, the water supply pipeline of the secondary pipe network and the return pipeline of the secondary pipe network. It should be noted that, in the present embodiment, the connection of the temperature sensor, the pressure sensor, the flow sensor, and the like to the pipe network is performed by the conventional technique, and the connection to the S2100 internet-of-things controller 10 and the response of the S2100 internet-of-things controller 10 by the signal transmission and reception are performed by the conventional control program.

As shown in fig. 2, the heat exchange station control cabinet of this embodiment is provided with a door 2 with a display unit 22 pivotally mounted on a cabinet body 1, and a sealing strip 21 is disposed between the door 2 and the cabinet body 1 to ensure a relatively sealed environment in the cabinet body 1. In order to facilitate better ventilation and heat dissipation of the S2100 internet-of-things controller 10, a ventilation device is arranged in the cabinet body 1, meanwhile, an air inlet 12 and an air outlet 13 are arranged on the cabinet body 1, as shown in figure 2, the ventilation device comprises a filtering device 3 positioned at the bottom of a cabinet body 1 and a drainage fan 4 connected with the filtering device 3, wherein, the filtering device 3 is shown in fig. 3 and 4, and mainly comprises a housing with an end cover, a first filter element 35 and a second filter element 36 which are nested in the housing and have different diameters and are cylindrical, a conical air inlet hole 31 is formed at the bottom of the housing, and an air outlet hole 32 is communicated with the inner cavity of the second filter element 36, the first filter element 35 and the second filter element 36 are screwed on the end cover, and a blowhole 33 is formed in the end cover at a position between the first filter element 35 and the second filter element 36.

Specifically, the air inlet 12 is communicated with an air inlet hole 31 of the filter device 3, an air outlet hole 32 of the filter device 3 is communicated with an air inlet of the drainage fan 4, an air outlet of the drainage fan 4 is provided with an air exhaust pipe 20, and the air exhaust pipe 20 is arranged in the ventilation channel, so that air flow can be introduced into the S2100 internet of things controller 10 and can be ventilated. In addition, a through hole is arranged on the cabinet body 1, and the through hole can be used for a pipeline communicated with the air blowing hole to pass through and be led out of the cabinet body 1, so that an external air source is conveniently communicated with the air blowing hole.

The air flow direction of the ventilation device of this embodiment in use can be as the arrow direction shown in fig. 4, that is, the air flow flowing into the cabinet body 1 through the air inlet 12 is sequentially filtered by the first filter element 35 and the second filter element 36, and is discharged from the inner cavity of the second filter element 36 through the air outlet 32. Certainly in order to facilitate the start-up of control fan and the ventilation of pipeline, this fan can adopt the mature servo motor of technology to control, can set up the valve simultaneously between fan and filter equipment 3, also can set up the valve on the pipeline of blowhole 33 intercommunication, in addition for the leakproofness that improves the cabinet body, all add the sealing washer in the mouth of blowing 11, air intake 12, air exit 13 and the threading mouth of pipe 14 department on the cabinet body to can effectively keep apart the inside that outside air current flowed into the cabinet body from the gap.

In addition, the blow holes 33 provided in the housing can be ventilated to the filter device 3 through the blow holes 33 by an external air source, so that the air flow can be reversed in the direction of the filter, i.e. in the direction of the arrows in fig. 4, by opening the valve at the blow hole, closing the valve between the filter unit 3 and the fan, then, air is blown into the filter device 3 through the air blowing holes, and dust attached to the outer peripheral wall of the second filter element 36 is discharged from the cavity between the first filter element 35 and the second filter element 36 to the outside through the first filter element 35, the dust attached to the first filter element 35 is directly discharged to the outside, and finally collected at the bottom of the casing and discharged to the outside of the cabinet body 1 through the tapered air inlet hole 31, the filter device 3 can be cleaned without disassembling the filter device 3, and the service life of the filter device 3 can be prolonged.

As shown in fig. 3 and 7, in order to facilitate the installation of the filtering device 3, a connection post is provided on the filtering device 3, and a screw hole 34 is formed on the connection post, thereby facilitating the installation of the filtering device 3 on the distribution board 5. Referring to fig. 2 and 5, the longitudinal section of the distribution board 5 of the present embodiment is in a structure like a Chinese character 'ji', that is, the middle horizontal plate is bent at two ends and extended to connect with the edge wing plates, so as to form a groove 53, wherein the groove 53 and the side plate of the cabinet body 1 together enclose to form the ventilation channel. Further, a plurality of elongated first mounting holes 51 are formed in the edge flap of the distribution board 5, and a plurality of elongated second mounting holes 52 are formed in the middle of the distribution board 5. Wherein the first mounting hole 51 is used for the fixed connection of the distribution board 5 and the cabinet body 1, and the second mounting hole 52 is used for the mounting connection of the S2100 internet-of-things controller 10 and the distribution board 5. In addition, the distribution board 5 has a structure like a Chinese character 'ji', has a simple structure, is convenient to process and manufacture, and has low cost.

As shown in fig. 5 and 6, the S2100 internet-of-things controller 10 is configured with a plurality of mounting holes, and a cylindrical rubber pad is provided between each mounting hole and the corresponding second mounting hole 52. Through the cylindrical rubber pads, on one hand, the S2100 Internet of things controller 10 can be damped, on the other hand, a certain gap is formed between the S2100 Internet of things controller 10 and the switchboard 5, and under the action of the second mounting holes 52, a better ventilation and heat dissipation effect can be achieved.

The utility model discloses a heat transfer station autonomous system based on S2100 thing networking controller through adopting S2100 thing networking controller 10, can make the load of heat source and heat supply network basically match to reduce the heating power imbalance of heat supply network, reach the purpose of even heat supply, can guide the load regulation of heat source factory simultaneously, reach real energy-conservation. In addition, through the ventilation unit who sets up, and the ventilation passageway of formation between distribution board 5 and cabinet body 1, not only can effectively carry out ventilation cooling to the S2100 thing networking controller 10 in the heat exchange station switch board, still can play better dustproof effect in the switch board of heat exchange station simultaneously, still reduce the humidity in the cabinet body 1 to a certain extent in addition, thereby can effectively guarantee S2100 thing networking controller 10 'S operational environment, in order to improve S2100 thing networking controller 10' S life, thereby can guarantee the normal operating of system, and there is better result of use.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. A heat exchange station automatic control system based on S2100 Internet of things controller is characterized by comprising: the heat exchange station comprises a heat exchange station, a primary pipe network and a secondary pipe network, wherein a heat exchange station control cabinet is arranged in the heat exchange station, the heat exchange station control cabinet comprises a cabinet body (1), a distribution board (5) which can be provided with an S2100 Internet of things controller (10) is fixedly arranged in the cabinet body (1), a ventilation channel is formed between the distribution board (5) and the cabinet body (1), and an air inlet (12) and an air outlet are formed in the cabinet body (1);

the ventilation device is arranged in the cabinet body (1), the ventilation device comprises a filtering device (3) communicated with the air inlet (12) and a drainage fan (4) connected with the filtering device (3) and positioned in the cabinet body (1), and the air outlet of the drainage fan (4) is connected with an exhaust pipe (20) which can be placed in the ventilation channel so as to form ventilation and heat dissipation of the S2100 Internet of things controller (10).

2. The S2100 internet of things controller-based heat exchange station autonomous system of claim 1, wherein: the vertical section of the distribution board (5) is of a structure in a shape like a Chinese character 'ji', a plurality of first mounting holes (51) in a long strip shape are formed on an edge wing plate of the distribution board (5), and a plurality of second mounting holes (52) in a long strip shape are formed in the middle of the distribution board (5).

3. The S2100 internet of things controller-based heat exchange station autonomous system of claim 2, wherein: a plurality of mounting holes are formed in the S2100 internet-of-things controller (10), and a cylindrical rubber pad is disposed between each mounting hole and the corresponding second mounting hole (52).

4. The S2100 internet of things controller-based heat exchange station autonomous system of claim 1, wherein: the filtering device (3) comprises a first filter element (35) and a second filter element (36) which are nested into a whole, have different diameters and are cylindrical, and the air inlet (12) flows through the air flow in the cabinet body (1) to be sequentially filtered by the first filter element (35) and the second filter element (36) and be discharged from the inner cavity of the second filter element (36).

5. The S2100 Internet of things controller-based heat exchange station autonomous system of claim 4, wherein: the filtering device (3) further comprises a shell with an end cover, wherein a conical air inlet hole (31) is formed in the bottom of the shell, the first filter element (35) and the second filter element (36) are in threaded connection with the end cover, and an air blowing hole (33) is formed in the position, located between the first filter element (35) and the second filter element (36), of the end cover.

6. The S2100 internet of things controller-based heat exchange station autonomous system of claim 1, wherein: a door body (2) provided with a display unit (22) is pivotally arranged on the cabinet body (1), and a sealing strip (21) is arranged between the door body (2) and the cabinet body (1).

7. The S2100 IOT controller based heat exchange station autonomous system of any one of claims 1 to 5, wherein: and a signal monitoring device is arranged on a water supply pipeline of the primary pipe network to monitor the temperature, pressure and flow of the water supply.

8. The S2100 internet of things controller-based heat exchange station autonomous system of claim 7, wherein: and a temperature sensor and a pressure sensor are arranged on the water return pipeline of the primary pipe network, the water supply pipeline of the secondary pipe network and the water return pipeline of the secondary pipe network.

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